Mechanisms underlying the control and generalization of sensorimotor learning

感觉运动学习的控制和泛化的机制

• 批准号: RGPIN-2017-04684
• 负责人: Gallivan, Jason
• 金额: $ 2.19万
• 依托单位: Queen's University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=651454
• 关键词: Mechanisms; underlying; control; generalization; sensorimotor

To cope with a continuously changing environment, the human brain has evolved an impressive ability to flexibly adjust, from one movement to the next, its motor commands. Such learning is a hallmark of any intelligent system and is central to human cognition and behaviour. Yet, the mechanisms that support sensorimotor learning and updating, and which allow acquired skills to be readily transferred to new contexts, remains poorly understood. The broad aims of the research program proposed here are to (1) better understand the mechanisms and strategies through which individuals learn sensorimotor tasks, (2) explore how this learning can be improved and better generalized, and (3) better understand the neural circuitry that supports sensorimotor learning and updating. The proposed research consists of three separate projects.******Project 1:***An important feature of the success of many well-learned skills is that they generalize to new contexts. Yet, the ways in which such generalization might be maximized has received very little attention and has important practical benefits for workplace, musical and sports training. PROJECT 1, by manipulating participant sensory feedback, will determine how skills acquired with one hand can be best generalized to the other, untrained hand. In addition, using neurostimulation tools, we will assess the causal neural mechanisms underlying this generalization.******Project 2:***Society often takes the view that, whereas the forgetting or loss of information is to be prevented and remedied, the retention of information is to be practised and improved. While this may be true of many of our declarative memories (e.g., remembering family members, facts, figures, etc.), it is critical that our motor systems have the capacity to suppress certain types of learning that can interfere with overall task performance. PROJECT 2 will test the hypothesis that the motor system, in situations in which the interference effects associated with learning two separate tasks overrides the gains associated with learning each of those tasks, will intelligently suppress learning the less valued task. ******Project 3:***Motor learning is often examined using adaptation tasks in which individuals are required to respond to unusual forces or changes in visual feedback. However, significant learning also occurs in standard everyday tasks, as when acquiring the weight of an object lifted for the first time. We recently showed that object weight information, gained through lifting, is represented in the ventral visual pathway. However, the causal role of this representation in object motor interactions remains unclear. PROJECT 3 will use functional MRI and neurostimulation tools to causally assess the role of the ventral visual pathway in weight encoding and determine how perturbing the activity of ventral visual areas disrupts the activity of interconnected regions in frontoparietal cortex.

为了应对不断变化的环境，人类大脑进化出了一种令人印象深刻的能力，能够灵活地调整运动指令，从一个动作到另一个动作。这种学习是任何智能系统的标志，也是人类认知和行为的核心。然而，支持感觉运动学习和更新的机制，以及允许所获得的技能容易地转移到新环境中的机制，仍然知之甚少。该研究项目的主要目的是(1)更好地了解个体学习感觉运动任务的机制和策略，(2)探索如何改进和更好地推广这种学习，以及(3)更好地了解支持感觉运动学习和更新的神经回路。拟议的研究由三个独立的项目组成。*项目1：*许多学得很好的技能成功的一个重要特点是，它们适用于新的背景。然而，最大限度地扩大这种概括性的方法很少受到关注，而且对工作场所、音乐和体育训练具有重要的实际好处。项目1，通过操纵参与者的感觉反馈，将确定如何将一只手获得的技能最好地推广到另一只未经训练的手。此外，使用神经刺激工具，我们将评估这种概括背后的因果神经机制。*项目2：*社会通常认为，虽然要防止和纠正信息的遗忘或丢失，但要练习和改进信息的保留。虽然这可能适用于我们的许多陈述性记忆(例如，记住家庭成员、事实、数字等)，但至关重要的是，我们的运动系统具有抑制某些类型的学习的能力，这些学习可能会干扰整体任务表现。项目2将测试这样一种假设，即在学习两个独立任务的干扰效应超过学习每个任务的收益的情况下，运动系统将智能地抑制学习价值较低的任务。*项目3：*经常使用适应任务来考察运动学习，在这些任务中，个体被要求对不寻常的力量或视觉反馈中的变化做出反应。然而，重要的学习也发生在标准的日常任务中，比如第一次获得举起的物体的重量时。我们最近发现，通过举起获得的物体重量信息在腹侧视觉通路中被表现出来。然而，这种表征在物体运动相互作用中的因果作用仍不清楚。项目3将使用功能磁共振成像和神经刺激工具，对腹侧视觉通路在体重编码中的作用进行因果评估，并确定干扰腹侧视觉区域的活动如何扰乱额顶皮质相互连接的区域的活动。